Tank panels and tanks formed therefrom

ABSTRACT

A portable steel tank panel that interlocks with additional structures (e.g., other tank panels and/or removable hinges) to form a temporary aboveground fluid storage structure is described.

RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No. 61/632,355, entitled “Steel Insulated Hinged Tank Panels for Large Diameter Storage Tanks” and filed on Jan. 23, 2012; U.S. Provisional Application No. 61/604,765, entitled “Tank Panels and Tanks Formed Therefrom” and filed on Feb. 29, 2012; U.S. Provisional Application No. 61/625,714, entitled “Flexible Tank Panel” and filed on Apr. 18, 2012; and U.S. Provisional Application No. 61/645,245, entitled “Rounded Tank Panels and Tanks Formed Therefrom” and filed on May 10, 2012, each of which is incorporated herein by reference in its entirety.

FIELD

Embodiments relate generally to storage tanks, and, more particularly, to tank panels and portable, temporary, aboveground, fluid storage tanks assembled from the tank panels.

BACKGROUND

Hydraulic fracturing, or “fracking,” is a process in which pressurized fluids fracture rock layers in order to release fossil fuels for extraction and recovery. Wellbore locations vary with rock formations, and temporary fluid storage near the wellbore's position is necessary. Water, which is used in hydraulic fracturing, is stored in “frac tanks” of various sizes and capacities. A need may exist to provide portable, temporary fluid storage tanks that can be configured to a variety of shapes and sizes.

Embodiments were conceived in light of the above-mentioned problems and needs, among other things.

SUMMARY

One embodiment includes a portable steel panel, which can be used to build temporary aboveground fluid storage tanks of a variety of sizes. The assembled tanks can be utilized during hydraulic fracturing procedures and other processes that need convenient large capacity fluid storage.

An embodiment can include an interlocking, hinged, optionally insulated, steel tank panel system that can be used to assemble temporary aboveground storage tanks.

An embodiment can be portable, temporary fluid storage tanks that can be assembled at any location or environment, and provide a temporary solution for fluid storage and liquid management.

One embodiment, includes a portable steel tank panel that interlocks with additional structures (e.g., other tank panels and/or removable hinges) to form a temporary aboveground fluid storage structure.

An embodiment can include a tank panel system including a panel having a flexible body section, a first endplate, a second endplate, a plurality of first panel pins, and a plurality of second panel pins, and a plurality of removable hinges each including a first side and a second side, wherein the first side and second side can be configured to be removably attached to a panel pin.

The panel can further include a lift point. The flexible body section can be formed of steel. The plurality of first panel pins can include a first group of panel pins each spaced a first distance apart and a second group of panel pins each spaced a second distance apart. The first distance can be larger than the second distance. The panel can further include an insulation coating applied to a surface of the panel.

Some implementations can include a tank panel system having a panel with a lower shell plate, an upper shell plate, a first endplate, a second endplate, a plurality of first panel pins, a plurality of second panel pins, a top pipe, and a bottom tube. The system can also include a plurality of removable hinges.

The panel can further include a lift point having a first lifting section tube, a second lifting section tube, a first lifting bar, a second lifting bar. The panel can include a plurality of stiffeners disposed on an inside area formed between a first wall of the panel and a second wall of the panel.

The plurality of first panel pins can include a first group of panel pins each spaced a first distance apart and a second group of panel pins each spaced a second distance apart. The first distance can be larger than the second distance. The panel can further include an insulation coating applied to a surface of the panel.

Some implementations can include a fluid tank having a plurality of panels joined together by a plurality of removable hinges at each joint between adjacent panels. Each panel can include a flexible body section, a first endplate, a second endplate, a plurality of first panel pins, and a plurality of second panel pins. Each panel can include a lower shell plate, an upper shell plate, a first endplate, a second endplate, a plurality of first panel pins, a plurality of second panel pins, a top pipe, and a bottom tube. The tank can include a first connecting member disposed between a first pair of panels and connected to the first pair of panels via a first group of removable hinges and a second group of removable hinges. The tank can also include a second connecting member disposed between a second pair of panels and connected to the second pair of panels via a third group of removable hinges and a fourth group of removable hinges. The tank can further include at least one brace member joining the first connecting member to the second connecting member via rotational joints.

The brace member can include a first brace member joining a top portion of the first connecting member to a top portion of the second connecting member and a second brace member joining a bottom portion of the first connecting member to a bottom portion of the second connecting member. The panels can be configured to form the fluid tank into an angled shape.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an example flexible tank panel and a plurality of removable hinges in accordance with at least one embodiment.

FIG. 2 is a section view through an example panel and liner in accordance with at least one embodiment.

FIG. 3 is a perspective view of two example panels joined with a plurality of removable hinges in accordance with at least one embodiment.

FIG. 4 shows an example of a full tank assembly without a liner in accordance with at least one embodiment.

FIG. 5 shows a diagram of an example hinge closed and locked for transport in accordance with at least one embodiment.

FIGS. 6A and 6B are perspective views of an exemplary single tank panel and a plurality of removable hinges in accordance with at least one embodiment.

FIG. 7 is a section view through an exemplary panel and liner.

FIG. 8 is a perspective view of two exemplary panels joined with a plurality of removable hinges.

FIG. 9 shows an exemplary full tank assembly without a liner.

FIG. 10 shows example connecting members with top and bottom brace members.

FIGS. 11 and 12 show detail views of an example connecting member.

FIG. 13 shows an example tank formed from tank panels, removable hinges and connecting members.

FIG. 14 shows an example tank having an angled shape formed from tank panels, removable hinges and connecting members.

DETAILED DESCRIPTION

FIG. 1 shows an exemplary tank panel system 100 having a tank panel 102 with a lower shell plate 104, an upper shell plate 106, a first endplate 108, a second endplate 110, a plurality of first panel pins 112, a plurality of second panel pins 114, a top pipe 116, a bottom tube 118, a first lifting section tube 120, a second lifting section tube 122, a first lifting bar 124, a second lifting bar 126 and a plurality of removable hinges 128.

The tank panel 102 can include the top pipe 116 to provide a more round shape for a liner to be placed over. Also, the top pipe 116 may be more flexible than the bottom tube 118, which may need to be stiffer due to the distribution of hydrostatic loads.

The first panel pins 112 are disposed on the first endplate 108. The second panel pins 114 are disposed on the second endplate 110. Each of the first panel pins 112 includes two holes through the panel pin. Each of the plurality of second panel pins 114 includes one hole through the panel pin.

The lower shell plate 104 and the upper shell plate 106 can be made of different materials and/or have different dimensions. For example, the lower shell plate 104 can be a plate about ½ an inch thick. The upper shell plate 106 can be a plate about ¼ of an inch thick. The lower shell plate 104 and the upper shell plate 106 can be made of steel, a composite material (e.g., carbon fiber, fiberglass, or the like) or other suitable material. The panel 102, and associated components, can be fabricated as a single unit from structural steel, or other suitable material, and can vary in height, width and length. Optionally, an insulation material, such as spray-on foam, can be applied to the panel 102. The foam insulation coating can also optionally have an exterior coating applied to help prevent UV or other damage to the foam.

The first panel pins 112 can be spaced a first distance apart on a portion of the first endplate 108 adjacent to the lower shell plate 104 and spaced a second distance apart on a portion of the first endplate 108 adjacent to the upper shell plate 106. For example, the first panel pins 112 may be spaced about 1′ 1″ apart adjacent to the lower shell plate 106 and may be spaced about 2 feet apart adjacent to the upper shell plate 104.

The first lifting section tube 120, the second lifting section tube 122, the first lifting bar 124 and the second lifting bar 126 form a lift point (or grappling device) for gripping the panel 102 with a machine for moving the panel 102 to construct a tank from a plurality of panels 102. The panel 102 can be lifted up and moved with the mechanical grappling device, which is designed to accommodate being placed in position by a crane or other lifting machine, which may include a grappling claw of a fork lift or lull.

Each of the removable hinges 128 can be connected to one of the first panel pins on a panel and to one of the second panel pins on an adjacent panel. The removable hinges can be secured in place with a hinge retaining pin that is placed through a hole in a respective one of the panel pins.

A group of panels 102 can be fastened (or connected) together using the removable hinges 128 to form a tank having hinged joints at the junction where two panels meet. The group of interconnected panels 102 can be assembled to form a temporary aboveground fluid storage tank. The interconnected tank panel system disclosed herein permits creation of multiple tank configurations, diameters and volumes according to a contemplated use. Also, by using panels, a tank can be shipped as components (e.g., panels, hinges and liner) and assembled on site.

Referring now to FIG. 2, a section of a tank panel system 100 is shown supporting a liner 202 system, which forms an interior containment area that prevents water or fluid leakage. A group of panels 102 can be connected to form a temporary above ground storage tank system 100, which can support a waterproof and leak-proof liner 202 system. The liner 202 is placed in the tank following the assembly of the panels 102 and can be secured to the top pipe 116 using an Omega shaped retaining member, for example. Once the liner is in place and secure, the tank can be filled with water or other fluid.

FIG. 3 shows two panels with removable hinges joined together as a tank panel unit 300. The tank panel unit 300 includes a first tank panel 302 and a second tank panel 304. FIG. 3 shows a first endplate 306 of the first tank panel 302 and a second endplate 308 of the second tank panel 304. A gap may be present between the removable hinges. To cover this gap, gap covering extensions 130 can be placed on the first endplate 108 (or second endplate 110). The gap covering extensions can include a piece of curved steel attached to the edge of the endplate, for example.

The tank panel unit 300 also includes a plurality of removable hinges 310 mounted on panel pins 312. As discussed above, each removable hinge can be mounted on a first panel pin protruding from the first tank panel endplate 306 and a second panel pin protruding from the second tank panel endplate 308. Each panel pin 312 includes at least one hole to accommodate a hinge retaining pin (not shown). The removable hinges 310 may be spaced unevenly along the tank panel edge, for example, more closely at a bottom of the panel 318 and further apart at a top of the panel 316.

FIG. 4 shows an example tank 400 assembled from panels (e.g., a group of panels with each panel being similar to that shown in FIG. 1, reference 102), which is formed by attaching separate panels 402 together. Removable hinges are attached on each lateral edge of each panel 402 to join adjacent panels together with a hinged joint. Grappling devices can be disposed on an interior or an exterior of the panels 402 making up the tank 400.

The tank's shape is based, in part, on the number of panels 402 used. As an assembled tank is filled with water, the panels flex and may seek an essentially round configuration. The hinged joint can help reduce or prevent moment stress at joints between adjacent panels and can transfer stress as tension along the length of the panels. Thus, a tank made from a group panels can be relatively light and flexible and can also contain large volumes of fluid, depending on the number of panels used to build the tank.

An embodiment can provide a portable, temporary fluid storage tank that can be assembled on location in various environments, and can provide a temporary solution for fluid storage and liquid management. Also, the tank panels can optionally have an insulating material applied to an interior or exterior side to help the tank retain heat in order to avoid having the liquid in the tank freeze in cold climates.

FIG. 5 shows details of a removable hinge 128 having a first hinge portion 502, a second hinge portion 504 and a hinge pin 506. As shown, the second hinge portion 504 has been folded over the first hinge portion 502. A hinge retaining pin 508 has been placed through a hole of a first panel pin 112 to secure the hinge 128 in a folded position for transportation or storage. The hole that the hinge retaining pin 508 is placed through in FIG. 5 is the outermost hole of the two holes in each of the first panel pins 112. When being used to connect panels for a tank, the hinge 128 can be opened and connected to one of the first panel pins 112 with a retaining pin placed through the innermost hole of the two holes and to one of the second panel pins with a retaining pin place through the hole in that pin.

FIG. 6 shows an exemplary tank panel system 600 having a tank panel 602 with a first side 604 and a corresponding first tank panel hinge bracket and a second side 606 and a corresponding second tank panel hinge bracket. Also shown is a plurality of removable hinges 608. Each hinge having a first hinge portion 614 and a second hinge portion 616. The first side 604 and second side 606 each have a plurality of boss members 612 protruding from a surface. The boss members 612 on each side are configured to mate with a corresponding opening in a respective first or second hinge portion (614, 616). The tank panel 602 also has a lift point 610 (or grappling device) for gripping the tank panel 602 with a machine for moving the panel and construction of a tank.

Removable hinges 608 can be connected to the sides of tank panels, which allows a plurality of panels 602 to be fastened together with a hinged joint to form a tank. The panel 602 can be lifted up and moved with the mechanical grappling device 610, which is designed to accommodate being placed in position by a crane or other lifting machine, which may include a grappling claw of a fork lift or lull. A group of interlocking panels 602 can be assembled to form a temporary aboveground fluid storage tank. The interlocking tank panel system disclosed herein permits creation of multiple tank configurations, diameters and volumes according to a contemplated use of an embodiment.

The panel 602, and associated components, can be fabricated as a single unit from structural steel and can vary in height, width and length.

Referring now to FIG. 7, a section of a tank panel system 600 is shown supporting a liner 702 system, which forms an interior containment area that prevents water or fluid leakage.

A group of interlocking panels 602 are assembled to form a temporary aboveground storage tank system 600, which can support a waterproof and leak-proof liner 602 system. The liner 602 is placed in the tank following the assembly of the panels 602 and the tank can be filled with water or other fluids.

FIG. 8 shows two panels with removable hinges joined together as a tank panel unit 800. The tank panel unit 800 includes a first tank panel 802 and a second tank panel 804. The second tank panel 804 includes a first tank panel hinge bracket 806 and the first tank panel 802 includes a second tank panel hinge bracket 808. A gap may be present between the tank panel hinge brackets (806, 808). To cover this gap, one of the tank panel hinge brackets can include a hinge gap cover 820, which can include a piece of curved steel attached to the edge of the tank panel hinge bracket, for example.

The tank panel unit 800 also includes a plurality of removable hinges 810 mounted on boss members 812. Each removable hinge can be removably mounted on a first boss protruding from the first tank panel hinge bracket 806 and a second boss protruding from the second tank panel hinge bracket 808. Each boss 812 includes a hole 814 to accommodate a locking pin (not shown).

The removable hinges 810 may be spaced unevenly along the tank panel edge, for example, more closely at a bottom of the panel 818 and further apart at a top of the panel 816.

FIG. 9 shows an exemplary assembled tank 900, which is formed by attaching separate panels 902 together. Removable hinges are attached on each lateral edge of each panel 902 to join adjacent panels together with a hinged joint. Grappling devices can be disposed on an interior or an exterior of the panels 902 making up the tank 900.

The tank's unique shape, which is formed by a system of interlocking panels 902 as described above, allows the tank to contain large volumes of fluid.

FIG. 10 shows a system 1000 having example connecting members (1002 and 1004) with top and bottom brace members (1006 and 1008, respectively).

FIGS. 11 and 12 show detail views of an example connecting member. In particular, a system 1100 shows two tank panels 1102 and 1104 (e.g., rigid panel 100 or flexible panel 600) joined by a connecting member 1106 having a top brace member 1108 and a bottom brace member 1110 leading to another connecting member (not shown). In FIG. 12, the plurality of hinges 1112 attaching the panels to the connecting member can be seen (two groups, one for the first panel and one for the second panel). Also, FIG. 12 shows a rotational hinge couple the top brace member to the connecting member (a rotational hinge can also be provided for the bottom brace member).

FIG. 13 shows an example tank 1300 formed from tank panels, removable hinges and connecting members.

FIG. 14 shows an example tank 1400 having an angled shape formed from tank panels, removable hinges and connecting members.

It is, therefore, apparent that there is provided, in accordance with the various embodiments disclosed herein, tank panels and tanks made from the tank panels.

While the invention has been described in conjunction with a number of embodiments, it is evident that many alternatives, modifications and variations would be or are apparent to those of ordinary skill in the applicable arts. Accordingly, Applicant intends to embrace all such alternatives, modifications, equivalents and variations that are within the spirit and scope of the invention. 

What is claimed is:
 1. A tank panel system comprising: a panel having a flexible body section, a first endplate, a second endplate, a plurality of first panel pins, and a plurality of second panel pins; and a plurality of removable hinges each including a first side and a second side, wherein the first side and second side are configured to be removably attached to a panel pin.
 2. The tank panel system of claim 1, wherein the panel further includes a lift point.
 3. The tank panel system of claim 1, wherein the flexible body section is formed of steel.
 4. The tank panel system of claim 1, wherein the plurality of first panel pins includes a first group of panel pins each spaced a first distance apart and a second group of panel pins each spaced a second distance apart.
 5. The tank panel system of claim 1, wherein the first distance is larger than the second distance.
 6. The tank panel system of claim 1, wherein the panel further includes an insulation coating applied to a surface of the panel.
 7. A tank panel system comprising: a panel having a lower shell plate, an upper shell plate, a first endplate, a second endplate, a plurality of first panel pins, a plurality of second panel pins, a top pipe, and a bottom tube; and a plurality of removable hinges.
 8. The tank panel system of claim 7, wherein the panel further includes a lift point having a first lifting section tube, a second lifting section tube, a first lifting bar, a second lifting bar.
 9. The tank panel system of claim 7, wherein the panel includes a plurality of stiffeners disposed on an inside area formed between a first wall of the panel and a second wall of the panel.
 10. The tank panel system of claim 7, wherein the plurality of first panel pins includes a first group of panel pins each spaced a first distance apart and a second group of panel pins each spaced a second distance apart.
 11. The tank panel system of claim 10, wherein the first distance is larger than the second distance.
 12. The tank panel system of claim 7, wherein the panel further includes an insulation coating applied to a surface of the panel.
 13. A fluid tank comprising: a plurality of panels joined together by a plurality of removable hinges at each joint between adjacent panels.
 14. The fluid tank of claim 13, wherein each panel includes a flexible body section, a first endplate, a second endplate, a plurality of first panel pins, and a plurality of second panel pins.
 15. The fluid tank of claim 13, wherein each panel includes a lower shell plate, an upper shell plate, a first endplate, a second endplate, a plurality of first panel pins, a plurality of second panel pins, a top pipe, a bottom tube.
 16. The fluid tank of claim 14, further comprising: a first connecting member disposed between a first pair of panels and connected to the first pair of panels via a first group of removable hinges and a second group of removable hinges; a second connecting member disposed between a second pair of panels and connected to the second pair of panels via a third group of removable hinges and a fourth group of removable hinges; and at least one brace member joining the first connecting member to the second connecting member via rotational joints.
 17. The fluid tank of claim 15, further comprising: a first connecting member disposed between a first pair of panels and connected to the first pair of panels via a first group of removable hinges and a second group of removable hinges; a second connecting member disposed between a second pair of panels and connected to the second pair of panels via a third group of removable hinges and a fourth group of removable hinges; and at least one brace member joining the first connecting member to the second connecting member.
 18. The fluid tank of claim 16, wherein the at least one brace member includes a first brace member joining a top portion of the first connecting member to a top portion of the second connecting member and a second brace member joining a bottom portion of the first connecting member to a bottom portion of the second connecting member.
 19. The fluid tank of claim 17, wherein the at least one brace member includes a first brace member joining a top portion of the first connecting member to a top portion of the second connecting member and a second brace member joining a bottom portion of the first connecting member to a bottom portion of the second connecting member.
 20. The fluid tank of claim 19, wherein the panels are configured to form the fluid tank into an angled shape. 